Photodiode for ultra high speed optical communication and fabrication method therefor

ABSTRACT

Disclosed is a photodiode having a p-type electrode of a mushroom shape. The p-type electrode is formed in a mushroom shape, so that the contact area faced by the spreading region of a dopant for the photodiode and the electrode can be minimized and the capacitance of the photodiode can be reduced. Further, the p-type electrode is configured to have a broader width in its upper end, thus allowing the wire bonding to be performed easily.

CLAIM OF PRIORITY

This application claims priority to an application entitled “PHOTODIODEFOR ULTRA HIGH SPEED OPTICAL COMMUNICATION AND FABRICATION METHODTHEREFOR,” filed in the Korean Industrial Property Office on Jan. 8,2002 and assigned Serial No. 02-959, the contents of which are herebyincorporated by reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to an optical receiving element, andparticularly to a photodiode used in an optical communication system.

2. Description of the Related Art

In the optical communication, an electrical signal is converted into anoptical signal at the transmitting end using a light emitting elementand then transmitted through a transmission line, such as an opticalfiber. The converted optical signal is converted back into an electricalsignal at the receiving end using a light receiving element, such as aphotodiode. Most widely used photodiodes have a mesa type structure.

FIG. 1 is a cross-sectional view of a conventional photodiode 10 havinga mesa type structure. As shown in FIG. 1, the non-doped InGaAs andp-InP are sequentially stacked at one end of an InP substrate 11 bymeans of a single crystal growing process. An u-InGaAs absorption layer12 of a mesa type and a p-InP window layer 13 are formed by etching.Thereafter, silicon nitride(SiNx) is stacked on the p-InP window layer13 so that an insulation layer 14 is formed, and a predetermined portionof the insulation layer 14 is etched so that a part of the p-InP windowlayer 13 has an opening. A p-type electrode 15 is provided on the openportion of the p-InP window layer 13. Meanwhile, a non-reflectioncoating is applied to the position corresponding to the p-InP windowlayer 13 on the other side of the InP substrate 11, so that a lightreceiving region 17 having a predetermined size and an n-type electrode16 are formed.

In the method of fabricating a photodiode of a mesa type as describedabove, the non-doped InGaAs and p-InP layers are stacked through thesingle crystal growth process. Further, the undesirable spreading of ap-type dopant, such as Zn or Cd, is not necessary.

The conventional photodiode having the mesa type structure, however, hasseveral drawbacks in that the non-doped InGaAs and the p-InP are formedas layers in the form of a mesa type, then exposed to the atmosphere. Assuch, the non-doped InGaAs and the p-InP materials can be oxidizedduring a fabrication process. This oxidation may cause a deteriorationin the quality of the optical element. In addition, a current leakagemay occur on the surface that is mesa-etched, i.e., the surface facingthe insulation layer, thereby reducing the life of the opticalcomponent. Moreover, the InGaAs film whose energy band gap is small, mayhave a larger current leakage, thus further deteriorating thereliability of the optical circuit.

Furthermore, in an ultra high-speed optical communication, thecapacitance of the optical circuit must be small which can be achievedby reducing the spreading region of the p-InP. The photodiode of arelated art, however, makes wire bonding by providing a p-type electrodeconnected directly to the spreading region of the p-InP. Therefore, itis difficult to reduce the area of the spreading region of the p-InP.

SUMMARY OF THE INVENTION

The present invention overcomes the above-described problems, andprovides additional advantages, by providing a photodiode used in anultra high-speed optical communication and its fabrication methodcapable of improving reliability and lowering the capacitance thereof,by preventing a current leakage and enabling easier subsequent wirebonding.

According to one aspect of the invention, a photodiode for ultra highspeed optical communication includes: a substrate; an absorption layerformed on an upper surface of the substrate; a window layer stacked onthe absorption layer; an insulation layer stacked on the window layerand having a predetermined hole formed thereon; a spreading region inwhich a predetermined dopant is spread on the part of the window layerfacing the hole; and, an upper electrode connected to the spreadingregion through the hole and formed in a mushroom shape above theinsulation layer.

According to another aspect of the invention, a photodiode for ultrahigh speed optical communication includes: an InP substrate; an InGaAsabsorption layer stacked on one side of the InP substrate; an InP windowlayer stacked on the InGaAs absorption layer; an insulation layerstacked on the InP window layer and having a predetermined hole formedthereon; a p-InP spreading region in which a p-type dopant is doped onthe part of the InP window layer facing the hole; a metal of electricalconductivity electrically connected to the p-InP spreading regionthrough the hole and formed in a mushroom shape above the insulationlayer.

According to a further aspect of the invention, a method for fabricatinga photodiode for ultra high speed optical communication includes thesteps of: preparing a predetermined semiconductor substrate in which aspreading region is included, wherein an absorption layer, a windowlayer, and an insulation layer are stacked in sequence on thepredetermined substrate, and the spreading region is formed by spreadinga predetermined dopant on the window layer through an opening formed onthe part of the insulation layer; forming a photoresist layer on theinsulation layer; forming a hole on the photoresist layer by means of aphotoetching method so that the hole is connected to the opening of theinsulation layer; forming a metal plated layer connected to thespreading region through the hole formed on the photoresist layer; and,removing the photoresist layer.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will be described in detail with reference to thefollowing drawing in which like reference numerals refer to likeelements wherein:

FIG. 1 is a cross-sectional view illustrating a general photodiode of amesa type;

FIG. 2 is a cross-sectional view illustrating a photodiode for ultrahigh speed optical communication according to a preferred embodiment ofthe present invention;

FIG. 3 is a photograph illustrating a metal of electrical conductivityas shown in FIG. 2, formed on a photodiode; and,

FIG. 4 a through FIG. 4 e are illustrative drawings showing the processof forming the metal of electrical conductivity shown in FIG. 3.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

The following detailed description will present a photodiode for ultrahigh speed optical communication and fabrication method thereofaccording to a preferred embodiment of the invention with reference tothe accompanying drawings. For the purposes of clarity and simplicity,well-known functions or constructions are not described in detail asthey would obscure the invention in unnecessary detail.

FIG. 2 is a cross-sectional view illustrating a photodiode 20 used in anultra high-speed optical communication system according to a preferredembodiment of the present invention, and FIG. 3 shows a photograph ofelectrical conductivity of the electrode formed on the photodiode 20shown in FIG. 2. As shown in FIG. 2, the inventive photodiode 20includes a u-InGaAs absorption layer 22 on which a non-doped InGaAs isstacked, is formed entirely on at one end of an InP substrate 21; anu-InP window layer 23 a on which a non-doped InP is stacked, is formedon the u-InGaAs absorption layer 22; and, an insulation layer 24 a onwhich a SiNx is stacked, is formed on the u-InP window layer 23 a.

A predetermined hole 24 b is formed on the insulation layer 24 a, and ap-InP spreading region 23 b on which a p-type dopant such as Zn isdoped, is formed on a predetermined region of the u-InP window layer 23a facing the through hole 24 b. The p-InP spreading region 23 b isextended up to a portion of the u-InGaAs absorption layer 22. The p-InPspreading region 23 b is connected to a p-type electrode 25 a providedthrough the hole 24 b. The p-type electrode 25 a connected to the p-InPspreading region 23 b through the hole 24 b is exposed above theinsulation layer 24 a and is formed in a mushroom shape above theinsulation layer 24 a. Namely, the height of the p-type electrode 25 adoes not coincide with the surface of the insulation layer 24 a, but isextended further above the insulation layer 24 a. The area at which thep-type electrode 25 a and the surface of the insulation layer 24 a faceeach other is narrower than the surface area of the p-InP spreadingregion 23 b and shaped, so that the farthest away the p-type electrode25 a is distant from the surface of the insulation layer 24 a, thebroader the p-type electrode 25 a becomes. As a result, a predeterminedspace is formed between the outer periphery of the p-type electrode 25 aand the insulation layer 24 a, whereby an air layer 25 b is obtained.Note that if the p-type electrode 25 a is broad enough, the process ofwire bonding is easier to implement.

Meanwhile, on the other side of the InP substrate 21, a non-reflectioncoating using a silicon nitride(referred as SiNx hereinafter) isperformed on the position corresponding to the p-InP spreading region 23b, so that a light receiving region 27 is formed. For the rest region,except for the light receiving region 27, the non-reflection coating isremoved, then an n-type electrode 26 using an electrical conductivitymetal is formed, thereby forming a photodiode 20.

Note that the development of the optical communication was a directresult of higher data transmission speed, and that the transmissionspeed in the optical communication largely depends on the transmissionspeed of an optical communication element, such as the photodiode 20.The photodiode 20 used in an ultra high-speed optical communication canimprove the transmission speed by increasing the transmission bandwidth.To this end, the smaller the resistance and the capacitance of anoptical element are, an increase in the transmission bandwidth can beachieved. As most optical elements today need to be as compact aspossible, the capacitance rather than the resistance plays a major roleon the transmission bandwidth in the optical communication systems, asnoted below mathematically.

The capacitance of the element for optical communication is given by thefollowing formula 1:

[Formula 1] $C = \frac{ɛ\quad A}{t}$

Here, A represents an active area activated as the photodiode receivesan optical signal, and ∈ and t represent a dielectric constant ofmaterial occupying the space between electrodes and the distance betweenelectrodes, respectively.

According to the formula 1, if the active area A becomes narrow and thedielectric constant ∈ becomes smaller and the distance t between theelectrodes becomes larger, then the capacitance C gets smaller.Therefore, in order to make the capacitance of the photodiode 20smaller, the p-InP spreading region 23 b, an active area, must beminimized and the dielectric constant ∈ must be reduced. To meet theseconditions, the photodiode 20 according to the present invention reducesthe p-InP spreading region 23 b by minimizing the contact area of thep-type electrode 25 a and the p-InP spreading region 23 b. This resultis achieved by having the p-type electrode 25 a formed in a shape suchthat the farther away the p-type electrode 25 a away from the surfacefacing the p-InP spreading region 23 b, the broader the p-type electrode25 a becomes in its width. As a result, the space between the surface ofthe insulation layer 24 a and the p-type electrode 25 a is filled withair of low dielectric constant, whereby an air layer 25 b is formed.Further, the air layer 25 b giving the shape of the p-type electrode 25a lowers the dielectric constant ∈ substantially.

As apparent from the foregoing, the present invention minimizes thecontact area of the p-type electrode 25 a and the p-InP spreading region23 b, thereby reducing the area for the active region of the opticalelement used in the optical communication. Therefore, the photodiode ofthe present invention is easy to apply to the ultra high speed opticalcommunication system and has sufficient space for the wire bondingthrough the formation of the p-type electrode 25 a in a mushroom shape.

Now, the process for forming the p-type electrode having a mushroomshape will be described hereinafter.

FIG. 4 a and FIG. 4 b depict the procedures of forming a photoresistlayer on a semiconductor substrate 40. As shown in FIG. 4 a, thesemiconductor substrate 40 includes a predetermined substrate 41, anabsorption layer 42, a window layer 43 a in which a spreading region 43b is included therein, and an insulation layer 44 a on which a hole 44 bis formed. Further, a photoresist is applied on the semiconductorsubstrate 40 so that a photoresist layer 45 a is formed as shown in FIG.4 b.

Thereafter, the hole 45 b is formed on the photoresist layer 45 a withuse of the photolithography method as shown in FIG. 4 c. The hole 45 bis formed in a cylindrical shape by photoetching the hole 44 b on theinsulation layer 44 a, then the process for forming the sidewalls isperformed, so that the hole 45 b has a broader shape in its upperportion. The hole 45 b is connected to the hole 44 b of the insulationlayer 44 a and shaped so that the width of the hole 45 b is broader asit moves farther away from the region facing the insulation layer 44 a.

FIG. 4 d shows that the metal 46 of electrical conductivity having amushroom shape is formed. The metal 46 of electrical conductivity isformed in a mushroom shape as the shape of the hole 45 b on thephotoresist layer 45 a becomes broader as it moves farther away from theinsulation layer 44 a. The metal 46 of electrical conductivity is formedby plating and serves as the p-type electrode, which is positionedhigher than the photoresist layer 45 a. As the spreading region 43 b ismade of semiconductor material, a predetermined metal layer (not shown)is deposited and formed on the window layer 43 a for a subsequentplating to be performed.

After the metal 46 of electrical conductivity is formed, the photoresistlayer 45 a is removed as shown in FIG. 4 e, then non-reflection coatingis applied on a rear side of the substrate 41, and the coating for therest region, except for the region corresponding to the spreading region43 b, is removed by means of a photoetching process, thus forming alight receiving region 47 a. An n-type electrode 47 b is formed on theregion where the non-reflection coating is removed using another metalof electrical conductivity, thereby completing the formation of aphotodiode.

As described above, the present invention forms the p-type electrode ofthe photodiode in a mushroom shape, thereby minimizing capacitance ofthe photodiode, while accomplishing the electrode of a structure inwhich the wire bonding is easy to apply. That is, in the photodiode of arelated art, there have been limitations in reducing the active area tosecure the area for performing the wire bonding on the p-type electrode.The photodiode according to the present invention, however, forms thep-type electrode of a mushroom shape, thereby minimizing the area facingthe p-InP spreading region as well as securing the area for the wirebonding.

In addition, the photodiode of the present invention lowers capacitanceby reducing the area for the p-InP spreading region. Also, the etchingprocess is not performed for the u-InGaAs absorption layer or the u-InPwindow layer stacked on the InP substrate, instead, a method ofspreading a p-type dopant on the u-InP window layer is adopted, thuspreventing the u-InGaAs absorption layer or the u-InP window layer frombeing exposed to the atmosphere and oxidized accordingly. Moreover, thecontact area of the u-InGaAs absorption layer with the insulation layeris blocked by the u-InP window layer, so that the u-InGaAs absorptionlayer is not exposed to the current leakage, thereby improving thereliability of the optical elements. Furthermore, the p-type electrodeis formed in a mushroom shape, whereby a sufficient bonding area issecured which in turn makes the wired bonding easy.

The foregoing embodiments and advantages are merely exemplary and arenot to be construed as limiting the present invention. The descriptionof the present invention is intended to be illustrative, not to limitthe scope of the claims. Many alternatives, modifications, andvariations will be apparent to those skilled in the art. In the claims,means-plus-function clauses are intended to cover the structuresdescribed herein as performing the recited function and not onlystructural equivalents but also an equivalent structure.

1. A photodiode for ultra high speed optical communication comprising: asubstrate; an absorption layer formed on upper surface of the substrate;a window layer stacked on the absorption layer; an insulation layerhaving a predetermined hole stacked on the window layer; a spreadingregion having a predetermined dopant spread on a part of the windowlayer facing the predetermined hole; and, an electrode having a mushroomshape disposed above the insulation layer and connected to one end ofthe spreading region through the predetermine hole, wherein theelectrode comprises an upper surface and a lower surface, the width ofthe upper surface of the electrode is substantially broader the lowersurface of the electrode, so that a space between the insulation layerand an outer periphery of the electrode forms a contact area for asubsequent wire boding.
 2. The photodiode according to claim 1, whereinother end of the spreading region is further extended up to a portion ofthe absorption layer.
 3. The photodiode according to claim 1, whereinthe space between the insulation layer and an outer periphery of theelectrode is filled with air of low dielectric constant.
 4. Thephotodiode according to claim 1, wherein a contact area between theupper electrode and the insulation layer is narrower than the surfacearea of the spreading region.
 5. A photodiode for ultra high speedoptical communication comprising: an InP substrate; an InGaAs absorptionlayer stacked on at one end of the InP substrate; an InP window layerstacked on the InGaAs absorption layer; an insulation layer having apredetermined hole stacked on the InP window layer, a p-InP spreadingregion in which a p-type dopant is doped on a part of the InP windowlayer facing the hole; and, a metal conducting element having a mushroomshape above the insulation layer electrically connected to the p-InPspreading region through the predetermined hole, wherein the electrodecomprises an upper surface and a lower surface, the width of the uppersurface of the electrode is substantially broader than the lower surfaceof the electrode, so that a space between the insulation layer and anouter periphery of the metal conducting element forms a contact area fora subsequent wire boding.
 6. The photodiode according to claim 5,wherein the other end of the p-InP spreading region is further extendedup to a part of the InGaAs absorption layer.
 7. The photodiode accordingto claim 5, wherein the space between the insulation layer and an outerperiphery of the electrode is filled with air of low dielectricconstant.
 8. The photodiode according to claim 5, wherein contact areamutually faced by the metal conducting element and the insulation layeris narrower than the surface area of the spreading region.